WO2019024341A1 - Method for constructing library of cell-free dnas in body fluids and application thereof - Google Patents

Abstract

A method for constructing a library of cell-free DNAs in body fluids, comprising directly acting a transposase or an endonuclease on a body fluid sample, fragmenting the cell-free DNAs within, and performing amplification to obtain a library. Also provided is a test kit using the present method for prenatal diagnosis or early detection of cancer.

Description

Library construction method of body fluid free DNA and application thereof Technical field

The invention relates to the field of sequencing technology, in particular to a library construction method of body fluid free DNA and its use in prenatal diagnosis and early detection of cancer.

Background technique

In 1948, French scientists Mandel and Matthes first detected DNA fragments that were free of extracellular DNA in human peripheral blood. These DNAs are mainly derived from fragmented chromatin after apoptosis or necrotic cells have been cleaved.

In 1997, Lu Yuming's research team from the Chinese University of Hong Kong found that there was fetal blood free DNA in the peripheral blood of pregnant mothers, which opened the door for genetic testing of pregnant women's peripheral blood. The gene detection technology of pregnant women's peripheral blood is called non-invasive prenatal diagnosis technology. The principle is that the fetal mother's DNA exists in the peripheral blood of pregnant mothers, and the blood free DNA of pregnant mothers can be sequenced and compared with mother DNA. Differences in single nucleotide polymorphisms separate fetal DNA for prenatal diagnosis (Lo et al, Am. J. Hum. Genet 64, 218-224 (1999)). At present, this technology is relatively mature at home and abroad. It mainly screens three common chromosomal diseases, namely T21 chromosomal abnormality (Down's syndrome), T18 chromosomal abnormality (Edward's syndrome) and T13 chromosomal abnormality (Padang's syndrome). Syndrome), the detection accuracy is as high as 99% or more.

In addition, Lyon et al. determined that there is a correlation between the level of blood free DNA in cancer patients and the degree of metastasis of malignant tumors, providing a theoretical basis for non-invasive diagnosis of cancer. Furthermore, the early detection technology of cancer is derived: in the pathological state of cancer, the number of free DNA released into the blood is significantly increased due to the increase in the number of apoptotic and necrotic cells; these DNAs themselves carry mutations unique to cancer cells, so they can pass the examination. The concentration or mutation state of blood free DNA determines the type of cancer and the progression of development (Morelli et al., Ann Oncol 26, 731-736 (2015)). Furthermore, mutations in genes such as K-ras and EGFR have been detected in blood free DNA of cancer patients. These findings can be applied to the early diagnosis of malignant tumors such as lung cancer and breast cancer.

It should be noted that the human body contains more than 400 cell types, each of which has the same set of genomes, but their gene expression levels have significant cell specificity. This is regulated by a cell-specific epigenome that includes DNA methylation, histone modifications, nucleosome localization, etc., through which information can be directly determined by means of a cell reference epigenome database. source. Recent studies have shown that implicit information in blood free DNA, including methylation and nucleosome localization, can be used for tissue traceability.

Among them, the methylation of blood free DNA can reflect the methylation level of the source tissue cells to a certain extent, and the degree and location of methylation of different types of tissue cells are different, so it can be used to judge which free DNA comes from Cell type. For example, Lo et al. reported a technique for detecting blood-free DNA methylation: blood-free DNA carries the methylation status of the cells from which it is derived, so it can be processed by bisulfite treatment and sequenced by blood. The basic analysis can be mapped to a specific cell type to achieve tissue traceability (Lo et al., PNAS 112: 5503-5512 (2015)). The study can be used in a variety of diagnoses, including prenatal diagnosis, cancer localization and tumor cell metastasis diagnosis, and immune system rejection in organ transplant patients. However, this method has the following drawbacks: (1) there are fewer methylation sites on the genome, and the concentration of blood free DNA itself is low, so the detection results are often not accurate; (2) the methylation sequencing step is cumbersome and may be This leads to the loss of a large amount of DNA methylation information, resulting in low sequencing quality and severe noise.

In addition, nucleosome localization information in cells can be used to distinguish between cell and tissue types. A large number of reports have reported that the length of blood free DNA is mostly concentrated at about 167 bp, which is consistent with the length of a nucleosome DNA, indicating that a large amount of blood free DNA is DNA encapsulated by nucleosomes. In 2016, Jay Shendure et al., after extracting free DNA from blood, constructed a sequencing library and used deep sequencing strategies to locate nucleosome information of blood free DNA into different types of cells, thereby enabling tissue traceability (Shendure et Al., CELL 164, 57-68 (2016); Speicher et al., Nature Genetics 48, 1273-1278 (2016)). However, the method directly extracts free DNA in the blood to build a library, and then uses the sequencing data of blood free DNA to analyze nucleosome localization. The naked DNA present in the blood will generate noise, interfere with the localization of normal nucleosome DNA, and ultimately lead to low efficiency of tissue traceability. Moreover, the method uses deep sequencing strategy, which makes the sequencing cost too high, and it is difficult to form a wide range in commercialization. Applications.

In addition, studies have reported chromatin open sequencing technology specifically targeting chromatin open regions: by lysing cells and Tn5 transposase treatment, inserting sequencing junctions in the open region of chromatin, and then by PCR amplification Amplification of all open chromatin regions was performed and library construction and sequencing were performed (Chang et al., Curr. Protoc. Mol. Biol. 109: 21.29.1-21.29.9). However, this technique just excludes the information of nucleosome DNA and therefore cannot be traced to tissue based on nucleosome DNA.

In summary, the current routine non-invasive prenatal diagnosis and early detection of cancer are completed by first extracting blood free DNA and then performing routine database construction. The following problems exist: (1) The content of free DNA in blood is low, during the database construction process. It is very easy to bring losses, resulting in failure to build a library or low detection sensitivity; (2) The existing method of database construction is to directly extract free DNA in the blood, and then perform sequencing of the extracted DNA. In the end, only the sequence or methylation information of blood free DNA can be obtained, and the nucleosome distribution information may be lost during the process of building the database. (3) The cost of sequencing is too high. Therefore, it is urgent to develop an efficient and sensitive blood free DNA construction method, and this method can be used to screen out nucleosome fragments of blood free DNA for tissue traceability.

Summary of the invention

In view of the above-discussed deficiencies in the prior art, the present invention aims to provide a method for library construction of bodily fluid free DNA, and its use in prenatal diagnosis and early detection of cancer. The invention directly attacks the body fluid by using the enzyme to fragment the free DNA and add the linker without extracting the free DNA from the body fluid, the steps are simple, the cost of building the library is low, and the micro-banking strategy of the free DNA of the body fluid can be realized. And in the process of building the library, the fragment information of the free nucleosome DNA of the body fluid is retained to the utmost.

The present invention achieves the above object by the following technical solutions.

In one aspect, the invention provides a method of library construction of free DNA from a body fluid sample, comprising:

(1) directly acting on a body fluid sample with an enzyme to fragment free DNA in a body fluid sample;

(2) Amplification of the fragmented DNA obtained in the step 1) to obtain a humoral free DNA library.

In a preferred embodiment, the body fluid is selected from at least one of blood, urine, and saliva. In the body fluid sample, there are two kinds of free DNA: one is nucleosome DNA bound to histones, and the other is unbound naked DNA. After the enzyme is applied, the naked DNA is cleaved into fragments of about 50 bp, and the nucleosome DNA may be cleaved into larger fragments due to binding to histones.

In a preferred embodiment, the enzyme is a transposase or an endonuclease; preferably, the transposase is a Tn5 transposase, and the endonuclease is a MNase or DNase enzyme.

Please note that both the transposase and the endonuclease can be directly applied to the body fluid sample. The difference is that the embodiment of the direct humoral challenge using the transposase can directly complete both the DNA fragmentation and the addition of the linker. The embodiment of the Dicer can only be fragmented, and the step of adding a linker needs to be performed separately separately.

In a preferred embodiment, step (1) comprises: transposing a body fluid sample containing free DNA using a transposase to fragment the free DNA and adding a linker sequence to obtain a linker sequence comprising DNA fragment

Preferably, the step (1) further comprises the step of performing nucleic acid extraction after fragmenting the free DNA and adding a linker sequence.

In a further preferred embodiment, the linker for the transposition reaction is a linker mixture which is prepared by the following steps:

1) annealing primer A: 5'-CTGTCTCTTATACACATCT-3' (SEQ ID NO: 1) and primer B: 5'-TCGTCGGCAGCGTCAGATGTGTATAAGAGACAG-3' (SEQ ID NO: 2) to obtain annealed product 1;

2) annealing primer A: 5'-CTGTCTCTTATACACATCT-3' (SEQ ID NO: 1) and primer C: 5'-GTCTCGTGGGCTCGGAGATGTGTATAAGAGACAG-3' (SEQ ID NO: 3) to obtain Annealing product 2;

3) The annealing product 1 and the annealing product 2 are mixed to obtain a joint mixture.

Preferably, the linker mixture is embedded with the transposase to obtain a transposase-embedded complex for use in a transposition reaction.

Further preferably, the linker mixture is embedded with a Tagment Enzyme Advanced V5S comprising a transposase; preferably, the volume ratio of the linker mixture to the Tagment Enzyme Advanced V5S is 1:20 to 1:25, preferably It is 1:24.5; preferably, the embedding is carried out at 22-28 ° C, preferably at 25 ° C for 40-80 min, preferably 60 min.

In a specific embodiment, preferably, the transposase-embedded complex is incubated with the body fluid sample under transposition reaction conditions to effect a transposition reaction.

For the transposition reaction, preferably, the volume ratio of the transposase-embedded complex to the body fluid sample is 1:50-1:80, preferably 1:62.5;

Preferably, the transposition reaction temperature is 35-40 ° C, preferably 37 ° C;

Preferably, the transposition reaction time is from 55 to 65 min, preferably 60 min.

In a specific embodiment of the invention employing a transposition reaction, the Tn5 transposase used has the property of randomly cleaving DNA, and the naked free DNA in the plasma (free DNA not entangled in histones) is cleaved by the Tn5 transposase. A small fragment of about 50 bp is formed, and nucleosome DNA (free DNA entangled on histones) remains longer than 50 bp. By PE50+10 sequencing, DNA fragments of different lengths can be distinguished to select nucleosome DNA sequences, and the apparent information of DNA sequences and regulatory regions such as promoters or enhancers of different genes and transcription can be analyzed. The degree of enrichment of the starting zone. Subsequent use of these apparent information can be used to construct the nucleosome DNA sequence obtained from the library for tissue traceability of blood free DNA.

In another preferred embodiment of the present invention, the step (1) comprises: treating a body fluid sample containing free DNA with an endonuclease to fragment the free DNA, and then in the resulting fragmented DNA Adding a linker sequence to both ends to obtain a DNA fragment comprising the linker sequence;

Preferably, the step (1) further comprises the step of performing nucleic acid extraction after fragmenting the free DNA.

In a preferred embodiment, the amplification in step (2) comprises two amplifications;

Preferably, after the first amplification, the number N of cycles that need to be supplemented is determined by qPCR as the number of cycles for the second amplification.

In a preferred embodiment, the method further comprises the step (3): cyclizing and enzymatically cutting the body fluid free DNA library obtained in the step 2);

Preferably, the cyclizing comprises denaturation of the double-stranded DNA in the body fluid free DNA library into single-stranded DNA, and then joining by oligonucleotide complementary pairing with a single-stranded DNA partial region; Further preferably, a mediated fragment: 5'-GCCATGTCGTTCTGTGAGCCAAGG-3' (SEQ ID NO: 4) is used in complementary pairing with the single-stranded DNA to effect cyclization;

Preferably, the digestion is performed using exonuclease I and exonuclease III to remove uncircularized DNA;

Preferably, step (3) further comprises the step of purifying the digested product; preferably, purifying using magnetic beads.

In a second aspect, the present invention also provides a method of obtaining apparent information of an individual, comprising:

(1) obtaining a body fluid free DNA library of an individual according to the method of the first aspect;

(2) Sequencing and analyzing the body fluid free DNA library obtained in the step (1) to obtain individual apparent information.

In a third aspect, the present invention provides a method for constructing a library of free DNA of a body fluid sample according to the first aspect or a method for obtaining an individual's apparent information according to the second aspect, in prenatal diagnosis and early detection of cancer the use of.

In a fourth aspect, the present invention also provides a method for prenatal diagnosis or early detection of cancer, which is as first as The method for constructing a library of free DNA of a body fluid sample or the method for obtaining apparent information of an individual as described in the second aspect is achieved.

In a fifth aspect, the present invention provides a kit for analyzing bodily fluid free DNA for prenatal diagnosis or early detection of cancer, comprising the reagent, primer, mediated fragment or the method used in the method according to the first aspect A combination of one or more of them.

Preferably, the kit comprises one or more of the following combinations:

Transposase Tn5 or MNase or Dnase enzyme;

Primer A: 5'-CTGTCTCTTATACACATCT-3' (SEQ ID NO: 1), primer B: 5'-TCGTCGGCAGCGTCAGATGTGTATAAGAGACAG-3' (SEQ ID NO: 2) and primer C: 5'-GTCTCGTGGGCTCGGAGATGTGTATAAGAGACAG-3' (SEQ ID NO :3);

Mediating fragment: 5'-GCCATGTCGTTCTGTGAGCCAAGG-3' (SEQ ID NO: 4);

The enzyme and/or reagent required for transposition, PCR amplification, enzymatic cleavage, ligation reaction.

Advantages of the present invention over the prior art

As described above, in the prior art, a method of extracting free DNA from a body fluid sample and then using Tn5 transposase to attack and build a library is generally employed. However, the traceability of these methods is not accurate and requires deep sequencing. High cost and other shortcomings.

The invention directly attacks the body fluid by using an enzyme (for example, a transposase or an endonuclease) to fragment the free DNA therein and add a linker, thereby realizing the direct establishment of the free DNA of the body fluid; the method of the invention is not only simple in steps, but also The cost of the library is low, and the loss of information during the sequencing process is also reduced, and the fragment information of the free DNA of the body fluid is retained to the utmost, and the information of the nucleosome DNA is retained. Therefore, the method for constructing a library for free DNA of body fluid provided by the present invention can not only realize a micro-banking strategy for free DNA of body fluid, but also obtain an apparent information of free DNA of body fluid. Organizational traceability can also be achieved by further analyzing and mining the obtained apparent information, especially the nucleosome DNA.

The method provided by the invention provides a new research method for the study of body fluid free DNA, and has a good application prospect in clinical applications such as prenatal diagnosis, early tumor discovery and new disease monitoring.

DRAWINGS

1 is a data diagram of determining the number of cycles of the platform period by qPCR in Example 1;

2 is a graph showing a sample amplification curve in Example 1;

3 is a graph showing the results of Agilent 2100 detection after partial sample magnetic beads in Example 1;

4 is a correlation between data obtained by sampling samples in Example 1;

5 is an enrichment diagram of the fragments obtained after sequencing in Example 1 in the transcription initiation region of the housekeeping gene and the silencing gene, respectively;

6 is a clustering result of sample sequencing data and tissue sequencing data in Example 1.

Detailed ways

To facilitate an understanding of the invention, the invention is set forth below. It should be understood by those skilled in the art that the present invention is not to be construed as limited.

Example 1 Library Construction and Apparent Information Analysis of Peripheral Blood Free DNA

This embodiment includes a series of steps such as plasma sample preparation, Tn5 direct transposition plasma, transposition DNA amplification, Tn5 database construction, PE50+10 sequencing, and nucleosome fragment screening. The Tn5 transposase was prepared according to the instructions of Vazyme's TruePrep Mini DNA Sample Prep Kit.

1 plasma sample preparation

1.1 plasma sample collection

Collect 10 mL of healthy human whole blood samples. Centrifuge at 1600 g for 10 min at 4 °C. The supernatant (ie plasma) was taken to a new 15 mL centrifuge tube.

1.2 plasma purification (either of the following two methods can be used)

1.2.1 Method 1:

Filter head filtration method: 3 mL of plasma was taken and filtered into a new EP tube (about 0.5 mL) with a 10 mL syringe and a 0.2 μm filter.

1.2.2 Method 2:

Secondary centrifugation: After the plasma was centrifuged at 16000 g for 10 min at 4 ° C, the supernatant was taken to a new 15 mL centrifuge tube.

2-part plasma transposition reaction (ie, the method of the present invention, directly using plasma for transposition reaction)

2.1 Preparation of Joint Mixture (Adapter Mix)

2.1.1 Reference primer name and sequence:

Primer A: 5'-CTGTCTCTTATACACATCT-3' (SEQ ID NO: 1)

Primer B: 5'-TCGTCGGCAGCGTCAGATGTGTATAAGAGACAG-3' (SEQ ID NO: 2)

Primer C: 5'-GTCTCGTGGGCTCGGAGATGTGTATAAGAGACAG-3' (SEQ ID NO: 3)

2.1.2 Dissolve primer A, primer B, and primer C to 100 μM using an annealing buffer.

2.1.3 Prepare the following reaction system separately, see Table 1:

Table 1 Preparation system of joint mixture

2.1.4 The annealing product 1 and the annealing product 2 were separately vortexed and shaken thoroughly, and the solution was briefly centrifuged to return the solution to the bottom of the tube. Placed in the PCR machine, the following reaction procedure was carried out: 75 ° C for 15 min; 60 ° C for 10 min; 50 ° C 10 min; 40 ° C 10 min; 25 ° C 30 min.

2.1.5 After the end of the reaction, the annealed product 1 and the annealed product 2 are mixed in an equal volume and mixed. Name it Adapter Mix and store at -20 °C.

2.2 Encapsulation of the linker mixture with the Tn5 transposase to obtain a transposase-embedded complex

2.2.1 Add the reaction components in turn in a sterile PCR tube, see Table 2; wherein Tagment Enzyme Advanced V5S contains 1000 U Tn5 transposase BGI V5S reagent (supplier: BGI, item number: BGE005S).

Table 2 Embedding system of linker mixture and Tn5 transposase

2.2.2 Use a pipette to gently blow and mix thoroughly.

2.2.3 The reaction was placed at 25 ° C for 60 min. The reaction product was named Tagment Enzyme Advanced Mix V5S and stored at -20 °C.

2.3 blood free DNA fragmentation

The plasma transposition system (see Table 3) was prepared. After the preparation on ice was completed, the mixture was uniformly mixed, and the transposition reaction was carried out at 37 ° C for 60 min on a constant temperature metal mixer.

Table 3 Plasma transposition reaction system

Extraction of plasma free DNA after transposition

3.1 Extraction was performed using a Magen blood free DNA extraction kit (MAGEN MD5432-01).

3.2 After completion of the transposition reaction, 25 μL of proteinase K and 35 μL of MagBind magnetic beads were added to a new 1.5 mL centrifuge tube.

3.3 Transfer the sample to a centrifuge tube containing proteinase K. Shake well for 5 seconds.

3.4 Add 700 μL of MLE to the sample and vortex to mix. Incubate for 15 minutes at 55 ° C with shaking.

3.5 Transfer to the magnetic stand and let stand for 5 to 10 minutes to adsorb the magnetic beads.

3.6 Carefully aspirate all solutions.

3.7 Add 320 μL of buffer MW1 and vortex for 15 seconds.

3.8 Transfer to the magnetic stand and let stand for 3 to 5 minutes to adsorb the magnetic beads. Carefully aspirate all solutions.

3.9 Add 320 μL of buffer MW2 and vortex for 15 seconds.

3.10 Transfer to the magnetic stand and let stand for 3 to 5 minutes to adsorb the magnetic beads. Carefully aspirate all solutions.

3.11 Repeat steps 3.9-3.10.

3.12 Centrifuge briefly to collect droplets from the tube wall. Transfer to the magnetic stand and carefully discard all solutions.

3.13 Air dry for 5-10 minutes.

3.14 Add 20 μL of buffer AE, mix by pipetting.

3.15 Allow to stand at room temperature for 3 minutes.

3.16 Transfer to the magnetic stand, let stand for 3 minutes, dissolve in the same way.

3.17 Transfer the DNA solution to a new 1.5 mL centrifuge tube.

3.18 Qubit detection concentration.

4 Fragmentation DNA amplification

4.1 Prepare the PCR reaction system in a 0.2 mL PCR tube according to Table 4.

Table 4 First amplification reaction system of transposition products

*Note: The DNA solution was the purified DNA solution obtained in the step 3.17 of Example 1, and the DNA solution used in the following Comparative Example 1 was the purified DNA solution obtained in the step 1.4 of Example 1.

N5 primer:

Pho-GAACGACATGGCTACGATCCGACTTTCGTCGGCAGCGTC (SEQ ID NO: 5);

N7 Primer:

TGTGAGCCAAGGAGTTGTTGTCTTCNNNNNNNNNTCTCGTGGGCTCGG (SEQ ID NO: 6),

NNNNNNNNNN is a sequence of 10 random bases, and each sample uses a different tag sequence.

4.2 Perform the first amplification according to the following parameters:

5 Q-PCR identification and secondary amplification

5.1 Preparation of Q-PCR reaction system (as shown in Table 5):

Table 5 Identification of the number of cycles by fluorescence quantitative PCR

5.2 qPCR according to the following parameters:

As shown in Fig. 1, in the qPCR linear amplification Rn/Cycle curve, the number of cycles corresponding to the plateau fluorescence intensity 1/3 is the number N of cycles that need to be added.

5.3 Perform the second amplification according to the following parameters:

Where N is the number of cycles determined in step 5.2 and the sample amplification curve is shown in Figure 2.

6 XP magnetic beads double selection

6.1 Check the volume in the PCR tube and add to 50 μL with NF-H ₂ O;

6.2 Add 40 μL magnetic beads (0.8×), mix by blowing, and let stand for 5 minutes at room temperature;

6.3 On the magnetic stand for 2 minutes, transfer the supernatant to the new tube (the DNA fragments in the supernatant are less than 350bp);

6.4 Add 35 μL magnetic beads (0.7×), mix and let stand at room temperature for 5 min;

6.5 on the magnetic stand for 2 minutes, remove the supernatant containing small DNA fragments and RNA;

6.6 kept on the magnetic base, add 150 μL of pre-cooled 80% ethanol twice (30s);

6.7 held on the magnetic base for 5 minutes to allow water to evaporate;

6.8 is eluted DNA, add 20μ LTE Buffer (AMBION AM9858), gently mix by pipetting, incubate for 5 min at room temperature;

6.9 On the magnetic stand for 2 minutes, transfer the supernatant to the new tube, do not suck the magnetic beads;

6.10 Qubit dsDNA High sensitivity assay (INVITROGEN Q32854) quantification

6.11 Agilent 2100 was tested on the sample. The test results are shown in Figure 3.

7 library cyclization and enzyme digestion

The single-strand mediated fragment used in 7.1 is: 5'-GCCATGTCGTTCTGTGAGCCAAGG-3' (SEQ ID NO: 4).

7.2 The resulting DNA solution was purified by 324.5 ng of step 6. 5 μL of single-strand mediated fragment (20 μM) was added and made up to 70 μL with sterile ultrapure water.

7.3 Transfer the 7.2 mixture to a thermocycler, react at 95 ° C for 3 min, and quickly place on ice for 10 min.

7.4 According to Table 6, a single-stranded DNA ligation reaction system was prepared, mixed uniformly, and rapidly centrifuged for 3 s.

Table 6 Single-stranded DNA ligation reaction system

*Note: In Table 6, the DNA mixture is the solution obtained in step 7.3.

7.5 Transfer to a thermocycler, react at 37 ° C for 60 min, and temporarily store at 4 ° C.

7.6 According to Table 7, the digestion reaction system was prepared, mixed uniformly, and centrifuged rapidly for 3 s.

Table 7 Single-strand DNA digestion reaction system

*Note: In Table 7, EXO I is exonuclease I and EXO III is exonuclease III.

7.8 Transfer to a thermocycler, react at 37 ° C for 30 min, and temporarily store at 4 ° C.

8 library recycling

8.1 Vortex and mix the PEG32 magnetic beads and aspirate a volume of 170 μL into 128 μL of the PCR product, and mix thoroughly by pipetting 10 times with a pipette. Incubate for 10 minutes at room temperature;

8.2 Centrifuge the EP tube briefly and place it in a magnetic stand to separate the magnetic beads and liquid. Carefully remove the supernatant after the solution has clarified (about 5 min);

8.3 Keep the EP tube in the magnetic stand and rinse the beads with 200 μL of freshly prepared 80% ethanol. Carefully remove the supernatant after incubating for 30 s at room temperature;

8.4 Repeat the previous step, rinsing twice in total;

8.5 keep the EP tube in the magnetic frame, open the cover and air dry for 10min;

8.6 Remove the EP tube from the magnetic stand and add 25 μL of sterile ultrapure water. Mix thoroughly by pipetting with a pipette and let stand for 5 min at room temperature. The reaction tube was briefly centrifuged and placed in a magnetic stand to separate the magnetic beads and the liquid. After the solution is clarified (about 5 min), the supernatant is carefully aspirated into a clean EP tube and stored at -20 ° C;

8.7 After purification, 1 μL of the product was measured for ssDNA concentration.

9 on the machine sequencing

The constructed library was prepared as DNB (DNA nanospheres) according to the operating instructions of the BGI-SEQ500 sequencer, wherein a library of 6 ng was used and RCA was reacted for 20 min. Sequencing was then performed on a sequencer using a conventional PE50+10 strategy.

It should be noted that sequencing of the blood free DNA library obtained according to the present invention can be achieved by low-depth sequencing.

10 offline data analysis

10.1 Perform quality filtering and comparison on the offline Fastq sequencing data to obtain the Bam file after the data comparison.

10.2 By pairing the double-ended fragments of the sequencing data, the full length and position information of each fragment is obtained.

10.3 By filtering the fragment size, retain large fragments (above 60bp), calculate the correlation between the samples of these fragments, and the enrichment of these fragments in the promoter and enhancer regions of different genes. The results are shown in Figures 4 and 5. Shown.

10.4 Cluster analysis of these fragment data with DNase-seq data from different tissues of the human body in the ENCODE database, the results are shown in Figure 6.

Comparative example 1

The present comparative example adopts the method of the prior art, that is, the transposition reaction is carried out after directly extracting blood free DNA, as follows:

1 Directly extract blood free DNA and perform transposition reaction

1.1 Direct extraction of blood free DNA from the purified plasma in step 1.2 of Example 1 (refer to step 3 of Example 1 for a specific method).

1.2 Prepare the Tn5 transposition reaction system according to Table 8. After the preparation on ice, mix well and place on a constant temperature metal mixer for 30 min at 37 °C. Gently oscillate in the middle.

Table 8 Transposition reaction system after blood free DNA extraction

1.3 Stop the reaction: Add 7.5 μL of 5×NT buffer, gently pipette 20 times, and let stand for 5 minutes at room temperature.

1.41.8× magnetic beads to recover DNA samples

1.4.1 XP magnetic beads (AGENCOURTA63882) were taken out from the refrigerator at 4 ° C, mixed, and allowed to stand at room temperature for 10 min.

1.4.2 Add 1.8×XP magnetic beads, mix by blowing 10 times, and let stand for 5 min at room temperature.

1.4.3 placed on the magnetic stand, allowed to stand for 2min, the magnetic beads are adsorbed, and the liquid becomes clear.

1.4.4 Remove the supernatant and leave 5μL. Do not suck the beads.

1.4.5 Add 150 μL of 80% ethanol, let stand for 30 s, and discard the supernatant.

1.4.6. Repeat step 6.5. Finally, dry the ethanol and dry it until the surface of the magnetic beads is not reflective.

1.4.7 Remove the PCR tube from the magnetic stand, add 24 μL of NF water to dissolve, blow 10 times to mix, and let stand at room temperature for 3 min.

1.4.8 On the magnetic stand, let stand for 1 min, the liquid is clear.

1.4.9 Transfer the supernatant to a new tube.

1.4.10 Qubit dsDNA high sensitivity detection kit (INVITROGEN Q32854) quantification.

After obtaining the DNA sample solution according to the step 1.4 of the present Comparative Example 1, the experiment was continued in accordance with the procedure 4-10 of Example 1, to analyze the large fragment (60 bp or more) in the library constructed according to the method of Comparative Example 1. The enrichment of promoter and enhancer regions of different genes, the results are shown in Figure 4.

As shown in FIG. 4, a comparative analysis of the results of Example 1 and Comparative Example 1 reveals that it is apparent that the correlation between the samples obtained according to the method (Example 1) of the present invention is higher than that of the existing method (pair The correlation between the samples of ratio 1) is higher.

As shown in Fig. 5, the enrichment effect obtained by the method (Example 1) of the present invention is remarkably enhanced as compared with the conventional method (Comparative Example 1).

As shown in FIG. 6, the sample data obtained by the method of the present invention and the data from different tissues of the human body are clustered by a clustering method, indicating that the method of the present invention can capture body fluid free DNA signals from different tissues of the human body. Interest can be further traced to the organization.

The applicant claims that the detailed method of the present application is described by the above embodiments, but the present application is not limited to the above detailed methods, that is, it does not mean that the present application must rely on the above detailed methods to implement. It should be apparent to those skilled in the art that any modification of the present application, the equivalent replacement of each raw material of the product of the present application, the addition of an auxiliary component, the selection of a specific manner, and the like, are all within the scope of protection and disclosure of the present application.

Claims (14)

1. A method for library construction of free DNA of a body fluid sample, comprising:

   (1) directly acting on a body fluid sample with an enzyme to fragment free DNA in a body fluid sample;

   (2) Amplification of the fragmented DNA obtained in the step 1) to obtain a humoral free DNA library.
2. The method according to claim 1, wherein in the step (1), the enzyme is a transposase or an endonuclease.
3. The method according to claim 2, wherein the transposase is a Tn5 transposase, and the endonuclease is a MNase or a DNase enzyme.
4. The method according to claim 1, wherein the step (1) comprises: transposing a body fluid sample containing free DNA by a transposase to fragment the free DNA and adding a linker sequence to obtain inclusion a DNA fragment of a linker sequence;

   Preferably, the step (1) further comprises the step of performing nucleic acid extraction after fragmenting the free DNA and adding a linker sequence.
5. The method according to claim 1, wherein the step (1) comprises: treating a body fluid sample containing free DNA with an endonuclease to fragment the free DNA, and then adding a linker at both ends of the obtained fragmented DNA a sequence to obtain a DNA fragment comprising a linker sequence;

   Preferably, the step (1) further comprises the step of performing nucleic acid extraction after fragmenting the free DNA.
6. The method of claim 4 wherein the linker for the transposition reaction is a linker mixture prepared by the following steps:

   1) annealing primer A: 5'-CTGTCTCTTATACACATCT-3' and primer B: 5'-TCGTCGGCAGCGTCAGATGTGTATAAGAGACAG-3' to obtain annealed product 1;

   2) annealing primer A: 5'-CTGTCTCTTATACACATCT-3' and primer C: 5'-GTCTCGTGGGCTCGGAGATGTGTATAAGAGACAG-3' to obtain annealed product 2;

   3) mixing the annealing product 1 and the annealing product 2 to obtain a joint mixture;

   Preferably, the linker mixture is embedded with the transposase to obtain a transposase-embedded complex for use in a transposition reaction;

   Further preferably, the linker mixture is embedded with a Tagment Enzyme Advanced V5S comprising a transposase; preferably, the volume ratio of the linker mixture to the Tagment Enzyme Advanced V5S is 1:20 to 1:25, preferably It is 1:24.5; preferably, the embedding is carried out at 22-28 ° C, preferably at 25 ° C for 40-80 min, preferably 60 min.
7. The method according to claim 6, wherein the transposase-embedded complex is incubated with the body fluid sample under transposition reaction conditions to effect a transposition reaction;

   For the transposition reaction, preferably, the volume ratio of the transposase-embedded complex to the body fluid sample is 1:50-1:80, preferably 1:62.5;

   Preferably, the transposition reaction temperature is 35-40 ° C, preferably 37 ° C;

   Preferably, the transposition reaction time is from 55 to 65 min, preferably 60 min.
8. The method according to any one of claims 1 to 7, wherein the amplification in the step (2) comprises two amplifications;

   Preferably, after the first amplification, the number N of cycles that need to be supplemented is determined by qPCR as the number of cycles for the second amplification.
9. The method of any of claims 1-8, further comprising:

   Step (3): cyclizing and digesting the body fluid free DNA library obtained in step 2);

   Preferably, the cyclizing comprises denaturation of the double-stranded DNA in the body fluid free DNA library into single-stranded DNA, and then joining by oligonucleotide complementary pairing with a single-stranded DNA partial region; Further preferably, a mediated fragment: 5'-GCCATGTCGTTCTGTGAGCCAAGG-3' is used in complementary pairing with the single-stranded DNA to effect cyclization;

   Preferably, the digestion is performed using exonuclease I and exonuclease III to remove uncircularized DNA;

   Preferably, step (3) further comprises the step of purifying the digested product; preferably, purifying using magnetic beads.
10. A method of obtaining individual apparent information, comprising:

    (1) The method according to any one of claims 1 to 9, obtaining a body fluid free DNA library of an individual;

    (2) Sequencing and analyzing the body fluid free DNA library obtained in the step (1) to obtain individual apparent information.
11. The method for constructing a library of free sample DNA of a body fluid sample according to any one of claims 1 to 9 or the method for obtaining apparent information of a subject according to claim 10 for use in prenatal diagnosis and early detection of cancer.
12. A method for prenatal diagnosis or early detection of cancer, the method for constructing a library for free sample of body fluid sample according to any one of claims 1 to 9 or the method for obtaining apparent information of an individual according to claim 10 achieve.
13. A kit for analyzing bodily fluid free DNA for prenatal diagnosis or early detection of cancer, comprising the reagent, primer, mediated fragment or one or more of the methods used in the method of any one of claims 1-9 The combination of items.
14. The kit according to claim 13, wherein the kit comprises one or more of the following combinations:

    Transposase Tn5 or MNase or Dnase enzyme;

    Primer A: 5'-CTGTCTCTTATACACATCT-3', primer B: 5'-TCGTCGGCAGCGTCAGATGTGTATAAGAGACAG-3' and primer C: 5'-GTCTCGTGGGCTCGGAGATGTGTATAAGAGACAG-3';

    Mediated fragment: 5'-GCCATGTCGTTCTGTGAGCCAAGG-3';

    The enzyme and/or reagent required for transposition, PCR amplification, enzymatic cleavage, ligation reaction.

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